KR100222775B1 - Joint detector of continuous small bag body - Google Patents

Abstract

In detecting the sealing part 3a of the continuous small bag 1 in which the accommodating part 2 and the sealing part 3a in which the article | item was accommodated alternately formed the strip | belt-shaped, in accordance with conveyance of the continuous small bag 1 In order to convey the physical energy capable of conducting the packaging material of the continuous small bag 1 to the one side of the accommodating part 2 and the one side of the sealing part 3a, the energy delivery means 13a and the continuous small bag 1 are conveyed. The energy detecting means 17 which conducts the continuous small sealing member 1 and alternately detects the amount of energy of physical energy emitted from the other surface of the receiving portion 2 and the other surface of the sealing portion 3a, and this energy. And a seam discrimination means (20) for discriminating the sealing portion (3a) based on the detection result of the detection means (17).

Description

Joint detection device of continuous small bag

The present invention relates to a seam detecting device for a continuous small bag which detects a sealing part of a continuous small bag having a belt shape in which an accommodating part and a sealing part are alternately formed.

One of the food production machines has a bag feeder.

This small bag injecting device is, for example, cutting a continuous small bag (so-called continuous small bag) containing accommodating instant noodles, powdered soup, etc. into a single small bag and putting it into the container.

Fig. 12 is a perspective view showing the continuous small bag 1 of the three-way sealing type.

This continuous small bag 1 is made by folding a band-shaped packaging material in two, and has an accommodating portion 2 and a sealing portion 3a in which seasoning powder soup or the like is contained, specifically, each accommodating portion 2. The left and right side surfaces are sealed by the sealing portion 3a, and the upper portion of each housing portion 2 is sealed by a separate sealing portion 3b.

In separating the continuous small bag 1 into a single small bag, the continuous small bag 1 is conveyed in the direction of the arrow A, and the sealing part 3a is detected using a joint detecting device and output from the joint detecting device. The sealing part 3a of the continuous small sealing body 1 is cut | disconnected by supplying the sealing part 3a to a cutting device based on a seam detection signal (detection signal of the sealing part 3a).

The conventional structure of the said seam detection apparatus is shown to following (1)-(5).

(1) A registration mark is printed on each sealing portion 3a of the continuous small bag 1 as described in Japanese Unexamined Patent Application Publication No. 59-1105.

And the sealing part 3a is discriminated based on optical recognition of this registration mark.

(2) As described in Japanese Patent Application Laid-Open No. 62-38228, a continuous small bag is fitted into a pair of movable thickness detection rollers.

And the extremely thin sealing part 3a is discriminated based on the roller movement amount.

(3) The concave portions of Figs. 12 and 13 (a) formed in the receiving portion 2 of the continuous small bag 1 as described in Japanese Patent Application Laid-open No. Hei 8-34417 filed by the present applicant ( The sealing part 3a is discriminated based on detecting 2a) (the one in which the accommodating part 2 was formed concave by accommodating an article) with a photoelectric switch, a limit switch, etc.

(4) As described in Japanese Patent Application Laid-open No. 7-301667 filed by the present applicant, a pair of electrodes are disposed to face each other with the continuous small sealing member 1 interposed therebetween.

And the sealing part 3a is discriminated based on the difference of the capacitance when the accommodating part 2 passes between the both electrodes, and the capacitance when the sealing part 3 passes between the both electrodes.

(5) As described in Japanese Patent Application Laid-open No. 7-318826 filed by the present applicant, a pair of adsorption pads 1 is fitted to face a pair of adsorption pads, and the receiving portion 2 When passing between the adsorption pads, the adsorbed continuous small encapsulation material 1 is adsorbed by the adsorbent pads, and when the sealing portion 3a passes between the adsorbent pads, the adsorbed continuous small encapsulation material 1 is adsorbed by only one adsorption pad. Let's do it.

And the sealing part 3a is discriminated based on detecting the internal pressure of both suction pads.

The packaging material of the continuous small bag has various materials such as resin, aluminum, paper, and the like. The packaging material made of paper aluminum is a form in which paper aluminum is attached to the surface of the resin sheet.

Moreover, the contents of various properties such as solids, powders, liquids, and gels are accommodated in the accommodating portion 2 of the continuous small bag 1, and the contents are non-uniform in filling density because they are thin or thick. have.

In addition, in addition to the above-mentioned three-way sealing type, the continuous small sealing member 1 has various forms such as four-way sealing type and fatigue packing type.

Fig. 13B shows a continuous small sealing body 1 of four-way sealing type.

The continuous small bag 1 is made of two pieces of packaging material in a band shape, and the left and right sides of each housing portion 2 are sealed by the sealing portion 3a, and the upper and lower portions of each housing portion 2 are sealed. It is in the form sealed by (3b) and (3c).

Fig. 13C is a surface view showing the continuous small bag 1 of the fatigue packaging type, and (d) is a rear view of the continuous small bag 1 of the fatigue packaging type.

The continuous small bag 1 is formed by rounding a band-shaped packaging material. The left and right sides of each housing portion 2 are sealed by the sealing portion 3a, and the back side of each housing portion 2 is sealed. It is in the sealed form by 3d).

FIG. 13A is a surface view of the continuous small sealing body 1 of the three-way sealing type.

However, in the apparatus of said (1)-(5), detection of the sealing part 3a was not able to be stably performed with respect to some continuous small sealing body 1 as shown below.

In the case of the apparatus (1), letters or drawings printed on the surface of the continuous small package 1 may be misidentified with the registration mark, or there may be no color difference between the registration mark and the packaging material and the registration mark may not be discriminated. There is.

In the case of the apparatus (2), there is a possibility that the thin portion resulting from the ubiquity of the contents may be discriminated from the sealing portion.

At the same time, if the contents are thin like a laver, the difference between the thicknesses of the accommodating portion 2 and the sealing portion 3a is small, so that the sealing portion 3a cannot be stably detected.

If the contents are solid again, the contents may be broken when inserted into the roller, the receiving portion 2 may be torn, or the receiving portion 2 may be perforated.

In the case of the apparatus (3), if the contents are thin like steam, since the concave portion 2a is not formed in the accommodating portion 2, the sealing portion 3a cannot be stably detected. In addition, if the four directions of the accommodating part 2 are sealed, since the recessed part 2a is not formed in the accommodating part 2, the sealing part 3a cannot be detected fundamentally.

In the case of the apparatus (4), if the packaging material of the continuous small bag 1 is aluminum, since the continuous small bag 1 itself becomes a huge electrode, the sealing portion 3a is not detected under the influence of the floating capacity.

In the case of the apparatus (5), if the packaging material of the continuous small sealing member 1 is made of a hard material such as aluminum, the sealing part may not be accurately absorbed due to the wrinkles on the surface, and thus pressure leakage may occur. There is a fear that the detection of the portion 3a is not performed stably.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described circumstances, and its object is to provide continuous sealing for stably detecting a sealing portion for various continuous sealing objects without being influenced by the material of the packaging material, the nature or type of the contents, and the sealing form. The present invention provides a device for detecting a seam of a delay.

1 is a side view schematically showing a first embodiment of the present invention;

Figure 2 shows an enlarged view of the ultrasonic wave and the attachment state of the ultrasonic wave

Longitudinal front view

Fig. 3 (a) shows the output signal of the oscillating circuit (b) shows the output signal of the amplifying circuit, (c) shows the output signal of the integrating circuit, and (d) shows the output signal of the discriminating circuit. Drawing

4 is a front view schematically showing a second embodiment of the present invention;

5 is a diagram corresponding to FIG. 4 showing a third embodiment of the present invention.

6 is a diagram corresponding to FIG. 2 showing a fourth embodiment of the present invention.

Fig. 7 is an equivalent diagram showing the fifth embodiment of the present invention.

8 is a diagram corresponding to FIG. 1 showing a sixth embodiment of the present invention.

Fig. 9 (a) shows an output signal of the amplifying circuit, and (b) shows an output signal of the discriminating circuit.

Fig. 10 is a view schematically showing a seventh embodiment of the present invention (a diagram showing a state in which the blow holes of the hot air blowout pipe are directed upward).

Fig. 11 is a diagram showing a state in which the ejection hole of the hot air jet pipe is inclined upwardly;

Fig. 12 is a perspective view showing a continuous small bag of three-way sealing type

Fig. 13 (a) is a surface diagram showing a three-way sealing type continuous sealing material; (b) is a surface drawing of a four way sealing type continuous sealing material; (c) is a surface diagram showing a fatigue packing type continuous sealing material. , (d) is a rear view showing a continuous bag of fatigue-packed type.

* Explanation of symbols for main parts of the drawings

1: continuous small delay

2: receptacle

3a: sealing part

13a: energy delivery means

17: energy detection means

20: seam determination means

The seam detecting device of the continuous small bag according to claim 1 detects the sealing portion of the continuous small bag having an accommodating portion in which the article is stored and the continuous small bag in the form of a band formed alternately. An energy discharging means for alternately discharging physical energy capable of conducting to one side of the accommodating part and one side of the encapsulating part, and conducting the continuous encapsulating member in accordance with the conveyance of the continuous small encapsulating material, and physical energy emitted from the other side of the accommodating part and the other side of the encapsulating part And an energy detecting means for alternately detecting the amount of energy of the sensor, and a joint determining means for discriminating the sealing portion based on the detection result of the energy detecting means.

According to the above means, when the continuous small encapsulation member is conveyed, physical energy is alternately transmitted to one side of the accommodating portion and one surface of the encapsulation portion, and the physical energy is conducted to the other side of the accommodating portion and the other side of the accommodating portion by conducting the continuous small encapsulation member.

In this case, since the conductivity of the physical energy is different in the receiving portion and the sealing portion, and a difference occurs between the amount of energy emitted from the receiving portion and the amount of energy emitted from the sealing portion, the sealing portion is determined based on this difference.

Therefore, the color difference between letters or drawing registration marks printed on the receiving portion and the packaging material, the thin portion caused by the ubiquity of the contents, the difference in the thickness of the receiving portion and the sealing portion, the shape of the recessed portion of the containing portion, The sealing part is stably detected without being influenced by nothing or the packaging material being aluminum.

In the seam detecting device of the continuous small bag according to claim 2, the energy sending means sends heat to one surface of the continuous small bag as physical energy, and the energy detecting means detects infrared rays as physical energy emitted from the other surface of the continuous small bag. It is characterized by.

According to the above means, when heat is sent to one side of the accommodating part and one side of the sealing part, heat is conducted to the continuous small bag, and infrared rays are emitted from the other side of the accommodating part and the other side of the sealing part.

In this case, since the conductivity of heat in the accommodating part and the sealing part is different, and a difference occurs between the amount of infrared light emitted from the accommodating part and the amount of infrared light emitted from the sealing part, the sealing part is determined based on this difference.

The seam detecting device of the continuous small bag according to claim 3 is characterized in that the energy discharging means does not transmit heat to the continuous small bag when the conveyance of the continuous small bag is stopped.

According to the above means, when the conveyance of the continuous small bag is stopped, heat is not supplied to the continuous small bag.

For this reason, the continuous small bag is not heated locally, and such a thing as the packaging material of the continuous small bag is dissolved or adversely affected by heat to the contents is prevented.

The joint detecting device of the continuous small bag according to claim 4 is characterized in that the energy transmitting unit transmits sound waves as physical energy and the energy detecting unit detects sound waves emitted from the other side of the continuous small container.

According to the above means, when sound waves are sent to one surface of the receiving portion and one surface of the sealing portion, the sound waves are conducted to the continuous small sealing member.

In this case, the conductivity (attenuation rate) of the sound waves in the receiving portion and the sealing portion is different, and there is a difference between the received wave level of the sound wave emitted from the receiving portion and the sound wave level of the sound wave emitted from the sealing portion. Is determined.

For this reason, in addition to improving safety compared to the case of using heat as physical energy, there is no fear that heat influences on the contents of the continuous bag.

Along with this, the speed at which sound waves pass through the continuous small bag is fast, and even if the conveying speed of the continuous small bag is increased, the sealing part can be stably detected, thereby improving productivity.

The seam detecting device of the continuous small bag according to claim 5 is characterized in that the energy sending means and the energy detecting means are arranged to face each other with the continuous small bag being inclined with respect to the direction in which the energy sending means and the energy detecting means cross at right angles to the conveying direction.

According to the said means, a sound wave is transmitted inclined with respect to one surface of a accommodating part, and one surface of a sealing part.

At this time, the sound wave is relatively linearly conducted in the sealing portion, and attenuated and refracted in the receiving portion.

As a result, the difference between the sound wave level of the sound wave emitted from the receiving portion and the sound wave level of the sound wave emitted from the sealing portion becomes large, so that the acoustic impedance of the packaging material and the acoustic impedance of the contents are relatively close to each other. Even if it is difficult to place, the sealing part can be stably determined.

(Example)

Next, the first embodiment of the present invention will be described with reference to Figs. 1 to 3, and in this embodiment, an example in which sound waves, specifically, ultrasonic waves are used as physical energy will be described. First, in Fig. 2, the base 11 has a substantially “co” -shaped cross section connected between the horizontal lower plate portion 11a and the horizontal upper plate portion 11b by the vertical connecting plate portion 11c. The cylindrical vibration absorbing member 12 is fixed to the upper surface of 11a.

The vibration absorbing member 12 is formed of rubber, and the ultrasonic wave transmitter 13a is mounted on the upper end of the vibration absorbing member 12.

The base 11 is fixed to the connecting plate portion 11c, and the L-shaped transfer table 14 having a cross section is fixed to the base 11, and a three-way sealed continuous sealing member 1 is formed on the upper surface of the transfer table 14. It is mounted.

1, the chuck 15 is arrange | positioned in the terminal part of the conveyance table 14 in the direction of the arrow A direction.

The chuck 15 grips the terminal portion on the arrow A direction side of the continuous small bag 1, and a conveying mechanism (not shown) which uses the conveying motor as a driving source pulls the chuck 15 in the direction of the arrow A. FIG. Therefore, the continuous small bag 1 is conveyed in the same direction along the upper surface of the conveying table 14.

The conveyance guide 16 is attached to the conveyance table 14 as shown in FIG.

The conveyance guide 16 is capable of positioning in the direction of an arrow B and a half arrow B which intersects at right angles to the conveying direction (arrow A direction) of the continuous small sealing body 1, and the continuous small sealing body 1 The conveyance vibration in the direction of arrow B and half arrow B of the continuous small sealing member 1 is reduced by contacting the sealing portion 3b of

In the conveyance table 14, the ultrasonic sending hole 14a is formed above the ultrasonic transmitting device 13a. As shown in Fig. 1, the oscillation circuit 13b is connected to the ultrasonic wave transmitter 13a, and the oscillation circuit 13b is operated, and as shown in Fig. 3 (a), the ultrasonic wave transmitter from the oscillation circuit 13b is shown. When the sinusoidal oscillation signal (e.g., 270 KHz) of a constant level is applied to the 13a, the lower surface (one surface) and the sealing portion 3a of the accommodating portion 2 from the ultrasonic wave transmitter 13a through the ultrasonic discharge hole 14a. Ultrasonic wave (corresponding to physical energy) is transmitted alternately on the lower surface (one surface).

Reference numeral 13 in Fig. 1 denotes energy transmitting means composed of an ultrasonic wave transmitter 13a and an oscillation circuit 13b.

As shown in Fig. 2, the vibration absorbing member 12 is fixed to the upper plate portion 11b of the base 11 above the ultrasonic wave transmitter 13a.

The ultrasonic wave absorber 17 is mounted on the lower end of the vibration absorbing member 12, and the ultrasonic wave receiver 17 and the ultrasonic wave receiver 13a are disposed to face each other by sandwiching the continuous small bag 1.

The ultrasonic wave receiver 17 corresponds to an energy detecting means, and ultrasonic waves detected by alternately detecting ultrasonic waves emitted from the upper surface (the other surface) of the receiving portion 2 and the upper surface (the other surface) of the sealing portion 3a. The electrical signal is output in accordance with the vibration level of the.

1, an amplifying circuit 18 is connected to the ultrasonic wave 17, and the amplifying circuit 18 amplifies the output signal from the ultrasonic wave 17. As shown in FIG.

Ultrasonic conduction is conducted with little attenuation if the acoustic impedance is constant (= when passing through the same material) at the extreme distance.

In this case, each sealing part 3a of the continuous small-sealing body 1 is integrally in contact with the lower surface part and the upper surface part of a packaging material.

Therefore, in each sealing part 3a, the ultrasonic wave incident on the lower surface part of the packaging material is transmitted to the upper surface part without being substantially attenuated and is emitted from the upper surface part.

On the other hand, each receiving portion of the continuous small encapsulation member 1 is formed by encapsulating the lower surface portion and the upper surface portion of the packaging material in the form of encapsulation, and the separated portion contains contents (liquid, solid, etc.), air, and the like. Therefore, it is necessary to pass the contents, air, and the like located in the separated portion of the packaging material when the ultrasonic wave is conducted from the lower surface portion of the packaging material to the upper surface portion.

Ultrasonic waves have the property of reflecting and attenuating a part of the boundary when acoustic impedance conducts between different materials.

For this reason, in the angle receiving portion 2, the ultrasonic wave incident on the lower surface portion of the packaging material is the interface between the lower surface portion of the packaging material and the air layer (or the contents in the receiving portion 2) of the packaging material, and the air layer in the receiving portion 2 ( Or attenuated at the interface between the contents in the receiving portion 2 and the upper surface portion of the packaging material and is only slightly fired from the upper surface portion of the packaging material.

Therefore, the output signal V from the amplifying circuit 18 becomes small in the accommodating part 2 and becomes large in the sealing part 3a as shown in Fig. 3B.

In addition, the reflectance R of the ultrasonic wave (the reflectance R of the energy of the wave incident perpendicularly to the interface of the two mediums in contact with each other in the plane) and the transmittance T are given by the following equation. Provided that Z ₁ and Z ₂ are the acoustic impedances of the two media in contact with each other.

R = (Z ₁ -Z ₂ ) ² / (Z ₁ + Z ₂ ) ²

T = 1-R

In addition, the acoustic impedance Z of various materials is shown next.

However, ρ is density, c is sound speed, and the specific value of sound speed c is as follows.

Z = ρ c

Water Z = 1.50 × 10 ^-6 [N sm ^-3 ]

Air Z = 428.6 [N sm ^-3 ]

Nylon Z = 2.86 × 10 ^-6 [N sm ^-3 ]

Water c = 1500 [ms ^-1 ]

Air c = 331.45 [ms ^-1 ]

Nylon c = 2620 [ms ^-1 ]

As shown in Fig. 1, an integrating circuit 19 is connected to the amplifying circuit 18, and the integrating circuit 19 integrates the output signal V from the amplifying circuit 18 as shown in Fig. 3C. The waveform is converted to an output signal Va.

In addition, the discrimination circuit 20 is connected to the integrating circuit 19 as shown in FIG.

This discrimination circuit 20 corresponds to a seam discriminating means, and as shown in Fig. 3C, the output signal Va from the integrating circuit 19 is compared with the preset reference level Vs and shown in Fig. 3D. As shown, when the output signal Va is larger than the reference level Vs, a high level signal is output.

An output circuit (buffer) 21 is connected to the discrimination circuit 20 as shown in FIG. 1, and the output circuit 21 is a high level joint detection signal S while the discrimination circuit 20 outputs a high level signal. Outputs

Therefore, the seam detection signal S is equivalent to the signal and waveform of the high level of the discrimination circuit 20 shown in Fig. 3D.

In addition, the vibration level of the ultrasonic wave detected on account of the slightly different acoustic impedance varies slightly depending on the material of the packaging material of the continuous small bag 1.

For this reason, the leveling volume 20 (not shown) is provided in the discriminating circuit 20, and the reference level Vs of the discriminating circuit 20 is continuously adjusted by operating the level adjusting volume.

As shown in FIG. 1, the base 11 is located in the direction of the arrow A direction of the ultrasonic wave transmitter 13a, and the cutting device 22 is arrange | positioned.

The cutting device 22 mainly consists of a fixedly arranged lower blade 22a and an upper blade 22b that can be moved up and down. When the seam detection signal S is output from the output circuit 21, the cutting device 22 is driven by the chuck 15. The conveyance operation | movement of the continuous small sealing body 1 is stopped, and the sealing part 3a is supplied between the lower blade 22a and the upper blade 22b. Then, the upper edge 22b is lowered and the middle portion of the sealing portion 3a is cut between the lower edge 22a and the upper edge 22b to separate a single envelope from the continuous envelope 1.

In addition, the seam detection signal S is output at the timing at which the boundary between the receiving portion 2 and the sealing portion 3a is supplied to the ultrasonic wave transmitter 13a as shown in Fig. 3D.

Therefore, the chuck 15 is stopped after conveying the continuous small bag 1 in the direction of the arrow A by a predetermined correction amount from the output of the seam detection signal S, and then stopped in the middle of the width direction (arrow A direction) of the sealing portion 3a. The part is positioned between the lower blade 22a and the upper blade 22b (see the sealing portion 3a indicated by the two-dot chain in Fig. 1).

The belt conveyor 23 is arrange | positioned below the base 11 at the arrow A direction side of the cutting device 22, as shown in FIG.

On the belt conveyor 23, a plurality of instantaneous containers 23a are mounted at a predetermined pitch (only one is shown), and the plurality of containers 23a are conveyed by the belt conveyor 23. As shown in FIG.

In addition, the belt conveyor 23 is arrange | positioned along the arrow B direction of FIG. 2, and the some container 23a flows in the same direction.

As shown in FIG. 1, a pusher 24 is disposed on the base 11 at the arrow A direction side of the cutting device 22.

The pusher 24 is configured to be movable up and down, and the pusher 24 is lowered when a single small bag is separated from the continuous small bag 1 by the cutting device 22.

The conveying table 14 is positioned below the pusher 24 to form an injection hole 14b, and the pusher 24 is a container 23a from the injection hole 14b of the small bag separated by the cutting device 22. Stab me in.

Next, the operation of the above-described configuration will be described.

The chuck 15 is first moved in the direction of the half arrow A to hold the terminal portion on the arrow A direction side of the continuous small bag 1, and then pulls the continuous small bag 1 in the direction of the arrow A. FIG. .

At this time, the cutting device 22 is temporarily evacuated so as not to interfere with the chuck 15.

When the continuous small bag 1 is pulled in the direction of the arrow A (when conveyed), the ultrasonic waves from the ultrasonic transmitter 13a are alternately transmitted and received on the lower surface of the accommodating portion 2 and the lower surface of the sealing portion 3a. It shoots through the upper surface of the part 2 and the upper surface of the sealing part 3a.

Here, when the accommodating part 2 passes above the ultrasonic wave transmitter 13a, the frequency level of the ultrasonic wave receiver 17 is small and the level of the output signal V from the amplifying circuit 18, that is, the integrating circuit 19 The level of the output signal Va is less than the reference level Vs.

For this reason, since the seam detection signal S is not output from the output circuit 21, the continuous small bag 1 continues to be conveyed in the direction of the arrow A by the chuck 15.

After that, when the sealing portion 3a reaches the upper side of the ultrasonic transmitter 13a, the receiving level of the ultrasonic wave receiver 17 becomes large and the level of the output signal Va from the integrating circuit 19 exceeds the reference level Vs. Therefore, the seam detection signal S is output from the output circuit 21.

When the seam detection signal S is output from the output circuit 21, the continuous small bag 1 is conveyed by the chuck 15 in the direction of the arrow A by a predetermined amount and stopped, and the intermediate portion of the sealing portion 3a is cut off ( 22).

Then, the upper edge 22b is lowered and the sealing part 3a is cut | disconnected with the lower edge 22a, and the small bag is separated from the continuous small bag 1 first.

Next, as the pusher 24 descends and the small bag is stuck into the container 23a through the feeding hole 14b, the above-described series of operations are repeated.

According to the above embodiment, the physical energy capable of conducting the packaging material of the continuous small encapsulation member 1 in accordance with the conveyance of the continuous small encapsulation member 1 is alternately applied to one surface of the accommodating portion 2 and one surface of the sealing portion 3a. Sent out.

Then, the sealing portion 3a is determined by conducting the continuous small sealing member 1 by alternately detecting the amount of physical energy emitted from the other surface of the receiving portion 2 and the other surface of the sealing portion 3a and comparing it with the reference level. did.

For this reason, whether the sealing part 3a is discriminated based on the optical recognition of the registration mark, unlike the conventional one, it is influenced by the color difference between the character or drawing registration mark printed on the receiving part 2 and the packaging material. This disappears.

In addition, unlike the conventional case in which the continuous small bag 1 is inserted into a pair of movable thickness detection rollers, there is no influence on the ubiquity of the contents and the thin thickness of the contents.

At the same time, there is no fear that the contents are cracked, the receiver 2 is torn, or a hole is drilled in the receiver 2.

Moreover, unlike the conventional case in which the sealing portion 3a is discriminated based on the recognition of the recessed portion 2a by a photoelectric switch or the like, the appearance of the recessed portion 2a is not affected by the presence or absence of the recessed portion 2a. .

In addition, unlike the conventional arrangement in which the pair of electrodes are disposed to face each other with the continuous small sealing member 1 and the conventional arrangement in which the pair of adsorption pads are opposed to each other, the packaging material is not affected by aluminum.

Therefore, the sealing part can be stably detected with respect to the various continuous small sealing bodies 1, without being influenced by the material of the packaging material, the property or type of the contents, the sealing form, and the like.

It also used sound waves as physical energy.

For this reason, compared with the case where heat is used as physical energy, for example, safety is improved, and there is no fear that heat influences on the contents of the continuous bag 1.

Along with this, the speed at which the sound waves pass through the continuous small bag 1 is high, and even if the conveyance speed of the continuous small bag 1 is increased, the sealing portion 3a can be stably detected, thereby improving productivity.

Specifically, ultrasonic waves were used as sound waves.

For this reason, since the directivity of physical energy becomes sharp, the detection precision of the sealing part 3a improves.

Moreover, because ultrasound is not an audible sound, there is no fear of making noise.

In addition, since the ultrasonic transmitter 13a is attached to the base 11 via the vibration absorbing member 12, the vibration of the ultrasonic transmitter 13a is absorbed by the vibration absorbing member 12.

Furthermore, since the ultrasonic wave absorber 17 is attached to the base 11 via the vibration absorbing member 12, the vibration transmitted from the ultrasonic wave transmitter 13a through the base 11 by the vibration absorbing member 12 Is absorbed.

Therefore, since vibration is prevented from being transmitted to the ultrasonic wave receiver 17, malfunction due to vibration noise of the ultrasonic wave receiver 17 is prevented.

Next, a second embodiment of the present invention will be described with reference to FIG.

In addition, the same code | symbol is attached | subjected about the same member as 1st Example, description is abbreviate | omitted, and only another member is demonstrated next.

The lower plate portion 11a and the upper plate portion 11b of the base 11 are inclined with respect to the arrow C direction (the direction crossing at right angles to the arrow A direction, which is the conveying direction of the continuous small package 1, see FIG. 1). 1), the vibration absorbing members 12 and 12 are arranged to face each other, and the ultrasonic wave transmitter 13a makes the ultrasonic wave inclined (non-orthogonally and non-horizontally) with respect to the lower surface of the continuous small bag 1. Songpa.

Ultrasound has the property of being transmitted linearly without refracting the same material (= when the acoustic impedance is constant).

Accordingly, in the sealing portion 3a in which the lower surface portion and the upper surface portion of the packaging material are integrated, ultrasonic waves incident on the lower surface portion of the packaging material linearly reach the upper surface portion of the packaging material and are emitted from the upper surface portion of the packaging material, as indicated by the one-dot chain.

In addition, when the acoustic impedance is conducted between different materials, a part of the reflected wave is reflected and attenuated at the interface, and a part of the incident wave is refracted.

For this reason, in the accommodating part 2, as shown by the dotted line, the ultrasonic wave incident on the lower surface part of the packaging material is the interface between the lower surface part of the packaging material and the contents in the accommodating part 2, the contents of the accommodating part 2 and the upper surface part of the packing material. It is attenuated and refracted at the interface and only slightly fired.

Therefore, the ultrasonic wave incident on the ultrasonic wave receiver 17 appears as a difference between the signal level which is larger at the receiving portion 2 and the sealing portion 3a.

In addition, the refractive index n of the ultrasonic wave is given by the following equation.

n = (inverse of sound speed c2 of second medium) / (inverse of sound speed c1 of first medium)

= (c1 / c2) / sinθ1 / sinθ2)

According to the above-described embodiment, the ultrasonic wave transmitter 13a and the ultrasonic wave receiver 17 are disposed to face each other by inserting the continuous small bag 1 inclined with respect to the arrow C direction, so that the ultrasonic wave is attenuated and refracted in the accommodating part 2. As a result, the receiving level of the ultrasonic wave receiver 17 is further reduced.

For this reason, since the difference in the received wave level of the ultrasonic wave receiver 17 increases in the accommodating part 2 and the sealing part 3a, even if the noise environment deteriorates, the sealing part 3a is stably performed.

In particular, when a resin sheet is used for the packaging material and the contents are liquid, the acoustic impedance of the packaging material and the acoustic impedance of the contents are relatively close.

For this reason, since there is little difference between the amount of attenuation of the ultrasonic waves in the accommodating portion 2 and the amount of the attenuation of the ultrasonic waves in the sealing portion 3a, the sealing portion 3a may not be stably discriminated if the noise environment is bad.

On the other hand, in the above-described embodiment, the ultrasonic wave is attenuated and refracted in the receiving portion 2, and the difference between the attenuation amount of the ultrasonic wave in the accommodating portion 2 and that of the ultrasonic wave in the sealing portion 3a increases. Even in a bad environment, the sealing portion 3a can be stably determined.

Next, a third embodiment of the present invention will be described with reference to FIG.

In addition, the same code | symbol is attached | subjected about the same member as 1st Example, description is abbreviate | omitted, and only another member is demonstrated next.

A vibration absorbing member (not shown) is fixed to the upper plate portion 11b (see FIG. 2) of the base 11.

The vibration absorbing member is mounted above the ultrasonic wave transmitter 13a, and the reflecting plate 25 is mounted, and the ultrasonic waves emitted from the upper surface of the continuous small bag 1 are reflected by the reflecting plate 25 and the path is perpendicular to each other. Refracted.

The ultrasonic wave absorber 17 is attached to the vibration absorbing member, and the ultrasonic wave reflected by the reflector 25 is incident on the ultrasonic wave absorber 17.

According to the above embodiment, the ultrasonic wave transmitter 13a and the ultrasonic wave receiver 17 are disposed so that an angle is formed between the wave direction of the ultrasonic wave receiver 13a and the wave direction of the ultrasonic wave receiver 17, and the ultrasonic wave wave is carried out. Ultrasonic waves from the group 13a were refracted by the reflecting plate 25 and applied to the ultrasonic wave receiver 17.

For this reason, since the direction of pulling out the lead wire of the ultrasonic wave receiver 17 can be changed, it is effective when the installation space of the ultrasonic wave receiver 17 is narrow.

Next, a fourth embodiment of the present invention will be described with reference to FIG.

In addition, the same code | symbol is attached | subjected about the same member as 1st Example, description is abbreviate | omitted, and only another member is demonstrated next.

11 d of through-holes are formed in the lower board part 11a and the upper board part 11b of the base 11, The rubber vibration absorbing member 26 is arrange | positioned in each of these through-holes 11d.

Each of these vibration absorbing members 26 is composed of a plate portion 26b having a hole 26a and a cylinder portion 26c positioned at the circumferential edge portion of the hole 26a, and each plate portion 26b has a through hole ( It is fixed to the peripheral edge part of 11d), and each cylinder part 26c is inserted in 11 d of through-holes.

And the ultrasonic wave transmitter 13a and the ultrasonic wave receiver 17 are mounted in the cylinder part 26c.

According to the above embodiment, the vibration absorbing member 26 is constituted by the flat plate portion 26b and the cylinder portion 26c, and the through hole 11d is formed in the base 11, and the cylinder portion 26c is the through hole 11d. Inserted).

For this reason, the height dimension of an apparatus can be made small compared with the case where the normal vibration absorption member 12 is fixed to the upper board part 11a and the lower board part 11b.

Next, a fifth embodiment of the present invention will be described with reference to FIG.

In addition, about the member same as 1st Example, the same code | symbol is attached | subjected, description is abbreviate | omitted, and only another member is demonstrated next.

The upper side of the vibration absorbing member 12 is equipped with an ultrasonic wave transmitter 13a, which is located at the lower end portion thereof. When the continuous small bag 1 is conveyed in the direction of arrow A (see Fig. 1), the upper surface of the receiving portion 2 and Ultrasonic waves are alternately transmitted to the upper surface of the sealing portion 3a.

The lower vibration absorbing member 12 is located at the upper end and is equipped with an ultrasonic wave detector 17, and the ultrasonic wave 17 emits ultrasonic waves emitted from the lower surface of the receiving portion 2 and the lower surface of the sealing portion 3a. By alternately detecting, the sealing portion 3a is discriminated as in the first embodiment described above, and the seam detection signal S is output from the output circuit 21.

Moreover, the normal sound insulation material 42 is arrange | positioned between the lower board part 11a of the base 11a, and the conveyance table 14 so that the ultrasonic wave receiver 17 may be enclosed.

According to the above embodiment, the ultrasonic wave receiver 17 is disposed in the closed space by the sound insulating material 42, the lower plate portion 11a, and the conveying table 14.

For this reason, the ultrasonic wave receiver 17 can stably detect the sealing part 3a without receiving acoustic noise from the outside.

In addition, although the ultrasonic waves were used as the sound waves corresponding to the physical energy in the first to fifth embodiments, the sound waves in the audible band may be used.

Incidentally, in the above first to fifth embodiments, the ultrasonic transmitter 13a is driven by the sine wave oscillation signal, but is not limited thereto. For example, the ultrasonic transmitter 13a may be driven by the pulse oscillation signal or the like. The ultrasonic wave may be transmitted continuously (= continuous or intermittent) from 13a).

In the first to fifth embodiments described above, the vibration absorbing members 12 and 26 are formed of rubber, but are not limited thereto. For example, the vibration absorbing members 12 and 26 may be formed of a soft resin such as urethane, elastomer, or the like. You may form by.

Next, a sixth embodiment of the present invention will be described with reference to Figs.

In this embodiment, an example in which heat is used as physical energy is shown.

In addition, about the member same as 1st Example mentioned above, the same code | symbol is attached | subjected, description is abbreviate | omitted, and only another member is demonstrated next.

First, in FIG. 8, the box 27 and 28 are fixed on the lower plate part 11a (refer FIG. 2) of the base 11, and a blowing pipe is provided between this box 27 and 28. In FIG. It is connected via 29a, and the blower pipe 29b is connected to the box body 28. As shown in FIG.

The fan apparatus 30 is arrange | positioned in the box 27.

The fan device 30 is a fan 30b attached to the rotation shaft of the fan motor 30a. When the fan 30b is rotated by the operation of the fan motor 30a, the inlet (not shown) of the box 27 is rotated. The outside air is sucked into the box body 27 and discharged into the box body 28 through the blowing pipe 29a.

Moreover, the heat source 31 is arrange | positioned in the box body 28. As shown in FIG.

This heat source 31 is made of a heat transfer coil, and the outside air discharged in the box body 28 is blown out by the heat source 31, hot-aired by the heat source 31, and then flows into the blowing pipe 29b.

The hot air blowing pipe 32 is connected to the blower pipe 29b.

The hot air blowing pipe 32 has a plurality of blowing holes 32a, and hot air flowing through the blowing pipe 29b flows into the hot air blowing pipe 32 and discharges upward through the plurality of blowing holes 32a. do.

Reference numeral 33 denotes energy delivery means including boxes 27 and 28, blown pipes 29a and 29b, fan device 30, heat source 31 and hot air blowout pipe 32. .

In the conveyance table 14, a plurality of hot wind flow holes 14c are formed above the hot air blow pipe 32, and hot air blown out from the plurality of blow holes 32a of the hot air blow pipe 32 (physical energy). The lower surface of the accommodating part 2 and the lower surface of the sealing part 3a are blown out alternately through the hot air flow hole 14c.

Then, the lower surface of the continuous small sealing body 1 is heated, and this heat is transmitted to the upper surface of the accommodating part 2 and the upper surface of the sealing part 3a by using the continuous small sealing body 1 as a medium. Infrared rays (corresponding to physical energy) are emitted from the top surface of the top surface and the top surface of the sealing portion 3a.

In addition, the heat source 31 is temperature-controlled so that hot air of about 100 ° C. may be ejected to the lower surface of the continuous small sealing member 1.

In this case, hot air of high temperature is blown out to the continuous small bag 1, but since the continuous small bag 1 is moved, there is no possibility of locally heating and there is no fear that the packaging material is dissolved or the contents are deteriorated.

The infrared detection element 34 is located above the hot air blowing pipe 32 at the terminal portion in the direction of the arrow A, and the infrared detection device 34 is fitted with the continuous small sealing member 1 and the hot air blowing pipe 32. It is arrange | positioned facing the terminal part.

The infrared detecting element 34 corresponds to an energy detecting means and alternately detects infrared rays emitted from the upper surface of the accommodating portion 2 and the upper surface of the sealing portion 3a, and outputs an electric signal corresponding to the detected infrared ray amount. .

An amplifying circuit 35 is connected to the infrared detecting element 34, and the amplifying circuit 35 amplifies and outputs an output signal from the infrared detecting element 34.

The heat conduction time in each sealing portion 3 of the continuous small sealing member 1 is approximately equal to the sum of the heat conduction time of the lower surface portion of the packaging material and the thermal conduction time of the upper surface portion.

On the other hand, each receiving portion 2 of the continuous small encapsulation member 1 is formed by encapsulating the lower surface portion and the upper surface portion of the packaging material in the form of an encapsulation material.

Therefore, in order to transfer heat from the lower surface portion of the packaging material to the upper surface portion, it is necessary to conduct heat to the contents and air located between the upper and lower portions.

Therefore, the heat conduction time in each accommodating part 2 becomes longer than the heat conduction time in the sealing part 3a.

In addition, the thermal conductivity k of various materials is referred to below.

Water k (0 ° C.) = 0.561 [W m ⁻¹ k ⁻¹ ]

Air k (0 ° C.) = 0.0241 [W m ⁻¹ k ⁻¹ ]

Nylon k (room temperature) = 0.27 [W m ^-1 k ^-1 ]

In the case of the continuous small sealing member 1 conveyed in the direction of arrow A, the time from the supply of the hot air blowing pipe 32 to the terminal portion on the side of the half arrow A direction until reaching below the infrared detection element 34 is measured in each portion. In the same way.

Therefore, since the heat quantity supplied to each part of the continuous small sealing body 1 becomes the same, the temperature of the upper surface of the accommodating part 2 is low and the upper surface of the sealing part 3a at the time when the lower part of the infrared detection element 34 reached | attained. The temperature of becomes high.

On the other hand, since the amount of infrared rays increases in proportion to the temperature, the output signal V from the amplifying circuit 35 is small in the accommodating part 2 and becomes larger in the sealing part 3a as shown in Fig. 9A.

The discrimination circuit 36 is connected to the amplifier circuit 35 as shown in FIG. This discriminating circuit 36 corresponds to a seam discriminating means, and as shown in Fig. 9A, the output signal V from the amplifying circuit 35 is compared with the reference level Vs set in advance in Fig. 9B. As shown in Fig. 2), when the output signal V is larger than the reference level Vs, a high level signal is output.

As shown in Fig. 8, an output circuit (buffer) 37 is connected to the discriminating circuit 35, and the output circuit 37 is a high level seam detection signal while the discriminating circuit 36 is outputting a high level signal. Output S

Therefore, the seam detection signal S is equivalent to the signal and waveform of the high level of the discrimination circuit 36 shown in Fig. 9B.

In addition, the amount of infrared rays detected also varies somewhat due to the somewhat different heat conduction time depending on the material of the packaging material of the continuous small-sealing body 1.

For this reason, the discrimination circuit 36 is provided with a level adjusting volume (not shown), and the reference level Vs of the discriminating circuit 36 is continuously adjusted by the operation of the level adjusting volume.

Next, the operation of the above-described configuration will be described.

When the continuous small sealing member 1 is conveyed in the direction of arrow A, hot air from the hot air blowing pipe 32 is alternately blown off the lower surface of the accommodating portion 2 and the lower surface of the sealing portion 3a, and the upper surface of the accommodating portion 2 And infrared rays are emitted from the upper surface of the sealing portion 3a.

Here, when the receiving portion 2 passes below the infrared detection element 34, the infrared detection amount of the infrared detection element 34 is small and the level of the output signal V from the amplifying circuit 35 is lower than the reference level Vs. have.

For this reason, since the seam detection signal S is not output from the output circuit 37, the continuous small sealing body 1 continues to be conveyed in the arrow A direction.

After that, when the sealing portion 3a reaches the lower side of the infrared detection element 34, the infrared detection amount of the infrared detection element 34 becomes large, and the level of the output signal V from the amplifying circuit 35 exceeds the reference level Vs. Therefore, the seam detection signal S is output from the output circuit 37.

When the seam detection signal S is output from the output circuit 37, as in the first embodiment described above, the continuous small bag 1 is conveyed in the direction of arrow A by a predetermined amount and then stopped.

And sticking of the small bag by the cutting pusher 24 of the sealing part 3a by the cutting device 22 is performed.

According to the above embodiment, physical energy capable of conducting the packaging material of the continuous small bag 1 is transferred to one surface of the accommodating part 2 and one surface of the sealing part 3a in turn according to the conveyance of the continuous small bag 1. .

Then, the sealing portion 3a was determined by alternately detecting the amount of physical energy emitted from the upper surface of the accommodating portion 2 and the other surface of the sealing portion 3a by inverting the continuous small sealing member 1.

For this reason, the color difference printed between the character or drawing registration mark printed on the accommodating part 2, and the packaging material, the ubiquity of the content, the thin thickness of the content, the appearance of the recessed part 2a, and the presence or absence of the recessed part 2a The sealing portion 3a is stably detected with respect to the various continuous small sealing bodies 1 without being affected by the packaging material being aluminum or the like.

In addition, since the hot air is used as the physical energy, the continuous small bag 1 is heated more rapidly than when the continuous small bag 1 is heated by radiant heat.

For this reason, since it is not necessary to reduce the conveyance speed of the continuous small sealing body 1 and to improve heating efficiency, it is prevented that the fall of productivity is caused.

Next, a seventh embodiment of the present invention will be described with reference to Figs.

In addition, about the member same as 6th Example, the same code | symbol is attached | subjected, description is abbreviate | omitted, and only another member is demonstrated next.

The blower pipe 29b shown in FIG. 8 is rotatably connected to the box body 28 in this embodiment, and the hot air blowing pipe 32 rotates with respect to the box body 28 integrally with the blower pipe 29b. do.

On the lower plate portion 11a (see FIG. 2) of the base 11, as shown in FIG. 10, the main body portion 38a of the cylinder 38 is fixed, and the pin 38 is attached to the rod 38b of the cylinder 38. 38c) is fixed.

In addition, the connection plate 39 is fixed to the hot air blowing pipe 32, and the connection plate 39 is formed with a long vertical hole 39a.

The pin 38c is inserted into the long hole 39a, and the connecting plate 39 is slidably and rotatably connected to the rod 38b via the pin 38c.

The cylinder 38 is connected to the control device 41 via the drive circuit 40, and when the control device 41 detects that the transfer motor of the transfer mechanism is driven, the continuous small bag 1 moves in the direction of arrow A. It judges that it is conveyed, and maintains the rod 38b of the cylinder 38 which protruded in the arrow B direction.

As a result, the plurality of blowing holes 32a of the hot air blowing pipe 32 are directed upward, and hot air is blown from the plurality of blowing holes 32a to the lower surface of the continuous small sealing member 1 to perform a seam detection operation.

In addition, when the control device 41 detects the stop of the transfer motor, the control unit 41 determines that the conveyance of the continuous small bag 1 is stopped, and outputs a transfer stop signal to the drive circuit 40, as shown in FIG. The rod 38b is moved in the direction of the half arrow B.

Then, the motive force of the rod 38b is transmitted to the connecting plate 39 via the pin 38c, and the pin 38c moves along the inner surface of the long hole 39a while the hot air blowing pipe 32 and the blowing pipe 29b are provided. Rotates with respect to the box body 28.

As a result, the plurality of blow holes 32a of the hot air blower pipe 32 are inclined upwardly and the supply of hot air to the continuous small bag 1 is stopped.

When the transfer motor is re-driven in this state, the control device 41 determines that the conveyance of the continuous small bag 1 is resumed, and releases the output of the transfer stop signal to the drive circuit 40, as shown in FIG. The rod 38b of the cylinder 38 is moved in the arrow B direction.

Then, the hot air jet pipe 32 is rotated and the plurality of jet holes 32a are directed upward while the pin 38c moves along the inner surface of the long hole 39a.

According to the said Example, when the conveyance of the continuous small bag 1 stopped, the continuous small bag 1 was not made to blow hot air.

For this reason, the continuous small sealing body 1 is not locally heated, and the packaging material of the continuous small sealing body 1 can be prevented from melt | dissolving and the bad influence by heat to the contents.

In this case, in order to stop supply of the hot air to the continuous small sealing member 1, it is possible to consider turning off the power supply of the heat source 31.

However, in this configuration, if the OFF time of the heat source 31 is long, it takes time for the heat source 31 to rise to a predetermined temperature after the power supply is turned on, so that there is a fear that the work efficiency is lowered.

In contrast, in the present embodiment, the hot air blowing pipe 32 is inclined to stop the supply of the hot air to the continuous small bag 1.

For this reason, since it is not necessary to turn off the power supply of the heat source 31, the fall of work efficiency is prevented.

Further, in the seventh embodiment described above, the hot air jet pipe 32 is rotated to stop the supply of the hot air to the continuous small bag 1, but is not limited thereto. For example, the transfer stop of the continuous small bag 1 is stopped. At the time, the power source of the heat source 31 may be turned OFF. In this case, since the cylinder 38, the connecting plate 39, etc. are unnecessary, the configuration is simplified (however, when the OFF time of the heat source 31 is long, the power is supplied to the heat source 31 again by canceling the output of the transfer stop signal. After that, it is preferable to delay the conveyance of the continuous small sealing member 1 by delaying the time until the temperature rises and the temperature stabilizes.

In the seventh embodiment described above, the hot air blowing pipe 32 is rotated by the cylinder 38, but is not limited thereto. For example, the hot air blowing pipe 32 may be rotated by an electric motor or the like.

Further, in the sixth and seventh embodiments described above, hot air is blown out on the lower surface of the continuous small sealing member 1, but the present invention is not limited thereto. It is good also as a structure which heats the lower surface.

In this configuration, since the heating power is weaker than that of the hot air, the continuous small bag 1 is started from the front of the infrared detection element 34 (half arrow A direction side) or the conveying speed of the continuous small bag 1 is increased. It is desirable to delay.

In the above sixth and seventh embodiments, the lower surface of the continuous small sealing member 1 is configured to be heated. However, the present invention is not limited thereto. It is good also as a structure which cools the lower surface of the continuous small sealing body 1 by blowing.

In the first to seventh embodiments described above, the high level seam detection signal S is output from the output circuits 21 and 37 by the detection of the sealing portion 3a, but the present invention is not limited thereto. A low level seam detection signal may be output.

In the first to seventh embodiments, the continuous small bag 1 related to food containing spices and the like is illustrated, but is not limited thereto. For example, the continuous small bag 1 for medical care in which medicines and the like are accommodated. It may be.

In the above first to seventh embodiments, reference level adjusting volumes are provided in the discriminating circuits 20 and 36, but the present invention is not limited thereto. For example, a plurality of memory units may be provided in a memory of a control device mainly composed of a microcomputer. The reference level Vs may be stored in advance, and the reference level Vs according to the type of the continuous small sealing member 1 may be read from the memory and set based on the operation of the selection switch.

In the first to seventh embodiments, the sealing portion 3a is configured to continuously adjust the reference level Vs of the discriminating circuits 20 and 36 so that the high level seam detection signal S is output. Instead, for example, the reference level Vs may be fixed or adjusted in stages.

In this configuration, since the output width (output time) of the seam detection signal changes but the interval from the start of the seam detection signal to the next start does not change (= conveyance pitch of continuous small bag 1), the sealing portion 3a. Supplying to the cutting device 22 does not interfere at all.

However, since the output timing of the seam detection signal is shifted, the intermediate portion in the width direction of the sealing portion 3a may not be supplied to the cutting device 22, so that the amount of corrected conveyance of the continuous small bag 1 by the chuck 15 is reduced. It is preferable to adjust (the conveyance amount of the continuous small bag 1 after the seam detection signal is output) and to supply the intermediate portion in the width direction of the sealing portion 3a to the cutting device 22.

In the above first to seventh embodiments, the conveyance of the continuous small bag 1 is stopped by the output of the seam detection signal S, and the sealing unit 3a is cut by the cutting device 22. For example, you may cut the sealing part 3a with the cutting device 22, conveying the continuous small sealing body 1, for example.

In this configuration, the upper blade 22b of the cutting device 22 may be lowered by the output of the seam detection signal S. FIG.

However, when the reference level Vs is fixed, the output timing of the seam detection signal is shifted when adjusting stepwise, so that the intermediate portion in the width direction of the sealing portion 3a is supplied to the cutting device 22 by the cutting device 22. It is also preferable to shift the cutting timing.

In addition, although the physical energy was transmitted to the lower surface of the continuous small sealing body 1 in the above sixth and seventh embodiments, the present invention is not limited thereto. For example, the physical energy may be transmitted to the upper surface. .

In this configuration, the amount of physical energy emitted from the lower surface of the continuous small sealing member 1 is detected.

As apparent from the above description, the seam detecting device of the continuous small bag of the present invention has the following effects.

According to the means described in Claims 1 and 2, physical energy capable of conducting the packaging material of the continuous small bag is sent out alternately to one side of the accommodating part and one side of the sealing part as the continuous small bag is conveyed.

Then, the sealing portion was determined by inverting the continuous small sealing member and alternately detecting the amount of physical energy emitted from the other surface of the housing portion and the other surface of the sealing portion.

For this reason, the color difference between letters and drawing registration marks printed on the accommodating part and the packing material, the thinness of the contents, the appearance of the concave part, the presence or absence of the concave part, and the packing material are not affected by various things. The sealing part is stably detected with respect to the continuous small bag.

According to the means of claim 3, the supply of heat to the continuous small bag is stopped in accordance with the stop of the conveyance of the continuous small bag.

Therefore, the continuous small bag is not heated locally, and the packaging material of the continuous small bag is prevented from being melted or adversely affected by heat in the contents.

According to the means of Claim 4, sound waves were transmitted as a physical energy to a continuous small-season member.

For this reason, compared with the case where heat is used as physical energy, the safety is improved, and the adverse effect on the contents of the continuous bag is prevented.

Along with this, the speed at which sound waves pass through the continuous small bag is fast, and even if the conveying speed of the continuous small bag is increased, the sealing part can be stably detected, thereby improving productivity.

According to the means of claim 5, sound waves were transmitted obliquely to the continuous small sealing member.

Therefore, the difference between the sound wave level of the sound wave emitted from the receiving portion and the sound wave level of the sound wave emitted from the sealing portion becomes large. Even in the case, the seal is stably determined.

Claims (5)

In detecting the sealing part 3a of the continuous small bag 1 which forms the strip | belt-shaped which the accommodating part 2 and the sealing part 3a in which the article was accommodated alternately, according to conveyance of the continuous small bag 1 Conveying the energy discharging means 13a for alternately discharging physical energy capable of conducting the packaging material of the continuous small bag 1 to one surface of the receiving part 2 and one surface of the sealing part 3a, and the continuous small bag 1 The energy detecting means 17 which conducts the continuous small sealing member 1 and alternately detects the amount of energy of physical energy emitted from the other surface of the accommodating portion 2 and the other surface of the sealing portion 3a. And a seam determination means (20) for discriminating the sealing portion (3a) based on the detection result of the energy detection means (17). The method of claim 1, The energy discharging means 13a transmits heat as physical energy to one surface of the continuous bag 1, and the energy detecting means 17 detects infrared rays as physical energy emitted from the other side of the bag. A seam detecting device for a continuous small bag. The method of claim 2, The energy sending means (13a) is a seam detecting device for a continuous small bag, characterized in that the heat is not sent to the continuous small bag (1) when the conveyance of the continuous small bag (1) is stopped. The method of claim 1, An apparatus for detecting a seam of a continuous small bag, characterized in that the energy transmitting means (13a) transmits sound waves as physical energy, and the energy detecting means (17) detects sound waves emitted from the other surface of the continuous small bag (1). The method of claim 1, Continuous firing, characterized in that the energy discharging means 13a and the energy detecting means 17 are disposed to face each other with the continuous small sealing body 1 inclined with respect to the direction crossing at right angles to the conveying direction of the continuous small sealing body 1. Retardation joint detection device.

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